The Top 10 Math Discoveries of 2025

The 10 Biggest Math Breakthroughs of 2025

By Clara Moskowitz edited by Andrea Thompson

This year has seen some amazing advancements in fundamental mathematics. Researchers have made breakthroughs in geometry, topology, chaos theory, and more. And a startling three of our top 10 discoveries involve the perennially fascinating prime numbers.

Without further ado, here are some of the most fascinating math findings Scientific American wrote about in 2025:

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A New Shape

A newfound shape called a noperthedron has 90 vertices, 240 edges and 152 faces. The baroque shape has a surprising property that disproves a long-standing geometrical conjecture: no matter how you shift or rotate it, one noperthedron can’t fall through a straight hole in an identical noperthedron.

Prime Number Patterns

Prime numbers, divisible only by themselves and 1, have long fascinated mathematicians. Discovering new ones is difficult as you get to larger and larger numbers. But this year mathematicians have found a set of probabilistic patterns that govern how the primes are distributed. The patterns involve random chaotic behavior and fractals.

A Grand Unified Theory

A “gargantuan” effort involving nine mathematicians and five papers spanning almost 1,000 pages recently proved the geometric Langlands conjecture. The conjecture connects the properties of different Riemann surfaces, which are structures with coordinates that have real and imaginary parts. It is part of a broader set of problems called the Langlands program, which, if fully proven, could provide a “grand unified theory of mathematics.”

Knot Complexity

A long-standing conjecture stated that if you attach the ends of two different knots to each other, the complexity of the new knot you create will be the sum of the individual knots’ complexity. But the recent discovery of a knot that is simpler than the sum of its parts disproves that assumption.

Fibonacci Problems

The Fibonacci sequence, in which each term is the sum of the previous two (1, 1, 2, 3, 5, 8, 13, …) shows up throughout nature. And now mathematicians have found that it also provides an answer to a variation of a classic quandary called the pick-up sticks problem: If you have a number of sticks with random lengths between 0 and 1, what are the chances that no three of those sticks can form a triangle?

Detecting Primes

The largest known prime number, 2^136,279,841 − 1, is 41,024,320 digits long, but mathematicians aren’t satisfied—they want to find even bigger primes. This year a team identified a new approach for finding undiscovered prime numbers. The strategy involves partitions, or ways numbers can add up to make other numbers.

125-Year-Old Problem Solved

In 1900 mathematician David Hilbert presented a series of major unsolved problems. One of them was the goal of determining the fewest possible mathematical assumptions behind the laws of physics. Researchers later broke up this task into subgoals, and this year mathematicians claimed to have completed one of them: they unified three physical theories to explain the motion of fluids. If the achievement is confirmed, it will be a major step toward solving Hilbert’s sixth problem.

Triangles to Squares

How many pieces must you cut a triangle into to be able to rearrange it into a square? In 1902 a newspaper reader found a way to do it with four pieces, but no one has managed to do it in fewer pieces since then. This year researchers finally proved that a triangle cut into fewer than four pieces cannot be turned into a square.

Moving Sofas

Anyone who’s moved houses can appreciate the dilemma of trying to fit a large couch around a corner. Mathematicians formally recognized the question around 60 years ago when they dubbed it the “moving sofa problem”: What is the largest shape that can turn a right angle in a narrow corridor without getting stuck? Researchers have now found a solution.

Catching Prime Numbers

Another breakthrough on the prime front is a new method for estimating how many prime numbers exist within any given range of numbers. The strategy first relies on eliminating all numbers that are multiples of other primes and therefore can’t be primes themselves. It then accounts for numbers that get crossed off the list more than once. The study’s authors also discovered a limit to how precise any estimate of this sort can be, showing that the fundamental mysteries of primes will remain elusive, at least for now.

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